rtic/rtic-monotonics/src/rp235x.rs

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//! [`Monotonic`](rtic_time::Monotonic) implementation for RP235x's Timer peripheral
//!
//!
//! Always runs at a fixed rate of 1 MHz.
//!
//! # Example
//!
//! ```
//! use rtic_monotonics::rp235x::prelude::*;
//!
//! rp235x_timer_monotonic!(Mono);
//!
//! fn init() {
//! # // This is normally provided by the selected PAC
//! # let timer = unsafe { core::mem::transmute(()) };
//! # let mut resets = unsafe { core::mem::transmute(()) };
//! #
//! // Start the monotonic
//! Mono::start(timer, &mut resets);
//! }
//!
//! async fn usage() {
//! loop {
//! // Use the monotonic
//! let timestamp = Mono::now();
//! Mono::delay(100.millis()).await;
//! }
//! }
//! ```
/// Common definitions and traits for using the RP235x timer monotonic
pub mod prelude {
pub use crate::rp235x_timer_monotonic;
pub use crate::Monotonic;
pub use fugit::{self, ExtU64, ExtU64Ceil};
}
use crate::TimerQueueBackend;
use cortex_m::peripheral::NVIC;
use rp235x_pac::Interrupt;
pub use rp235x_pac::{timer0, RESETS, TIMER0};
use rtic_time::timer_queue::TimerQueue;
/// Timer implementing [`TimerQueueBackend`].
pub struct TimerBackend;
impl TimerBackend {
/// Starts the monotonic timer.
///
/// **Do not use this function directly.**
///
/// Use the prelude macros instead.
pub fn _start(timer: TIMER0, resets: &RESETS) {
resets.reset().modify(|_, w| w.timer0().clear_bit());
while resets.reset_done().read().timer0().bit_is_clear() {}
timer.inte().modify(|_, w| w.alarm_0().bit(true));
TIMER_QUEUE.initialize(Self {});
unsafe {
crate::set_monotonic_prio(rp235x_pac::NVIC_PRIO_BITS, Interrupt::TIMER0_IRQ_0);
NVIC::unmask(Interrupt::TIMER0_IRQ_0);
}
}
fn timer() -> &'static timer0::RegisterBlock {
unsafe { &*TIMER0::ptr() }
}
}
static TIMER_QUEUE: TimerQueue<TimerBackend> = TimerQueue::new();
impl TimerQueueBackend for TimerBackend {
type Ticks = u64;
fn now() -> Self::Ticks {
let timer = Self::timer();
let mut hi0 = timer.timerawh().read().bits();
loop {
let low = timer.timerawl().read().bits();
let hi1 = timer.timerawh().read().bits();
if hi0 == hi1 {
break ((u64::from(hi0) << 32) | u64::from(low));
}
hi0 = hi1;
}
}
fn set_compare(instant: Self::Ticks) {
let now = Self::now();
const MAX: u64 = u32::MAX as u64;
// Since the timer may or may not overflow based on the requested compare val, we check
// how many ticks are left.
// `wrapping_sub` takes care of the u64 integer overflow special case.
let val = if instant.wrapping_sub(now) <= MAX {
instant & MAX
} else {
0
};
Self::timer()
.alarm0()
.write(|w| unsafe { w.bits(val as u32) });
}
fn clear_compare_flag() {
Self::timer().intr().modify(|_, w| w.alarm_0().bit(true));
}
fn pend_interrupt() {
NVIC::pend(Interrupt::TIMER0_IRQ_0);
}
fn timer_queue() -> &'static TimerQueue<Self> {
&TIMER_QUEUE
}
}
/// Create an RP235x timer based monotonic and register the necessary interrupt for it.
///
/// See [`crate::rp235x`] for more details.
///
/// # Arguments
///
/// * `name` - The name that the monotonic type will have.
#[macro_export]
macro_rules! rp235x_timer_monotonic {
($name:ident) => {
/// A `Monotonic` based on the RP235x Timer peripheral.
pub struct $name;
impl $name {
/// Starts the `Monotonic`.
///
/// This method must be called only once.
pub fn start(timer: $crate::rp235x::TIMER0, resets: &$crate::rp235x::RESETS) {
#[no_mangle]
#[allow(non_snake_case)]
unsafe extern "C" fn TIMER0_IRQ_0() {
use $crate::TimerQueueBackend;
$crate::rp235x::TimerBackend::timer_queue().on_monotonic_interrupt();
}
$crate::rp235x::TimerBackend::_start(timer, resets);
}
}
impl $crate::TimerQueueBasedMonotonic for $name {
type Backend = $crate::rp235x::TimerBackend;
type Instant = $crate::fugit::Instant<
<Self::Backend as $crate::TimerQueueBackend>::Ticks,
1,
1_000_000,
>;
type Duration = $crate::fugit::Duration<
<Self::Backend as $crate::TimerQueueBackend>::Ticks,
1,
1_000_000,
>;
}
$crate::rtic_time::impl_embedded_hal_delay_fugit!($name);
$crate::rtic_time::impl_embedded_hal_async_delay_fugit!($name);
};
}